Turbine with smart pitch system and blade pitch lock assembly

We claim: 1. A system comprising: a blade pitch system having a set of locking holes; a pitch drive assembly coupled to the blade pitch system and configured to rotate clockwise and, alternately, counterclockwise within a range of angular degrees to adjust a blade pitch angle; a pitch lock pin-and-hole system including an interface plate and at least one blade pitch lock assembly coupled to the interface plate, each blade pitch lock assembly including a locking pin having a pin center axis parallel with a center axis of a locking hole to engage a respective one locking hole of the set of locking holes in a locked state to lock the blade pitch angle; a rotor having a rotor housing and rotor drive assembly having a center rotor axis of rotation, the rotor drive assembly coupled to the pitch drive assembly; and a plurality of blades interfaced with the rotor housing in spaced relation to radiate from the rotor housing, wherein as the rotor housing rotates the plurality of blades rotate. 2. The system of claim 1 , further comprising: at least one processor having program instructions stored therein which when executed causes the at least one processor to: determine a blade pitch angle for generation of power by a turbine based on fluid flow after a low blade loading condition; disengage said each blade pitch lock assembly at the low blade loading condition to initiate a pitch angle adjustment sequence while the turbine is in a non-power generation mode; during the non-power generation mode of the turbine, adjust the blade pitch angle of a blade to correspond to the determined blade pitch angle; reengage said each blade pitch lock assembly to lock the blade pitch angle; and activate the turbine to generate power in a power generation mode with the blade continuously locked to the determined blade pitch angle during the power generation mode. 3. The system of claim 2 , wherein the low blade loading condition comprises a low blade loading period corresponding to one of slack tide and non-power generation mode of the turbine. 4. The system of claim 1 , wherein the blade pitch system comprises a wheel including a circular shape with the set of locking holes arranged circumferentially around and in proximity to an outer edge of the wheel. 5. The system of claim 1 , wherein said each blade pitch lock assembly further comprises: a housing mounted to the interface plate, the housing having a receptacle configured to receive the locking pin; and a locking pin articulation mechanism configured to, in response to a first control signal, disengage the blade pitch lock assembly by retracting the locking pin into the receptacle and, in response to a second control signal, engage the blade pitch lock assembly by ejecting the locking pin into an aligned locking hole in the blade pitch system. 6. The system of claim 1 , further comprising a linking arm coupled to the interface plate and the pitch drive assembly, the linking arm follows the rotation of the pitch drive assembly. 7. The system of claim 1 , wherein the blade pitch angle for generation of power by a turbine is based on fluid flow after a low blade loading condition wherein the low blade loading condition corresponds to slack tide. 8. A system comprising: a turbine including an energy generator, a nacelle, a rotor coupled to the nacelle, and a plurality of blades; and a plurality of smart pitch systems coupled to the plurality of blades, each smart pitch system comprising: a blade pitch system having a set of locking holes; a pitch drive assembly coupled to the blade pitch system and configured to rotate clockwise and, alternately, counterclockwise within a range of angular degrees to adjust a blade pitch angle of a respective one blade in a plane perpendicular to a rotor center axis of rotation; and a pitch locking pin-and-hole system including an interface plate and at least one blade pitch lock assembly coupled to the interface plate, each blade pitch lock assembly including a locking pin having a pin center axis parallel with a center axis of a locking hole to engage a respective one locking hole of the set of locking holes in a locked state to lock the blade pitch angle, wherein the blade pitch angle for generation of power by the turbine is based on fluid flow after a low blade loading condition. 9. The system of claim 8 , further comprising: at least one processor having program instructions stored therein which when executed causes the at least one processor to control each smart pitch system to: determine the blade pitch angle for generation of the power by the turbine based on the fluid flow after the low blade loading condition; disengage said each blade pitch lock assembly at the low blade loading condition to initiate a pitch angle adjustment sequence while the turbine is in a non-power generation mode; during the non-power generation mode of the turbine, adjust the blade pitch angle of a blade to correspond to the determined blade pitch angle; reengage said each blade pitch lock assembly to lock the blade pitch angle; and activate the turbine to generate power in a power generation mode with the blade continuously locked to the determined blade pitch angle during the power generation mode. 10. The system of claim 9 , wherein the low blade loading condition comprises a low blade loading period corresponding to one of slack tide and non-power generation mode of the turbine. 11. The system of claim 8 , wherein the blade pitch system comprises a wheel including a circular shape with the set of locking holes arranged circumferentially around and in proximity to an outer edge of the wheel. 12. The system of claim 8 , wherein said each blade pitch lock assembly further comprises: a housing mounted to the interface plate, the housing having a receptacle configured to receive the locking pin; and a locking pin articulation mechanism configured to, in response to a first control signal, disengage the blade pitch lock assembly by retracting the locking pin into the receptacle and, in response to a second control signal, engage the lock assembly by ejecting the locking pin into an aligned locking hole in the blade pitch system. 13. The system of claim 8 , wherein: the rotor comprises a rotor housing and rotor drive assembly having the center rotor axis of rotation, the rotor drive assembly coupled to the pitch drive assembly; and the plurality of blades interfaced with the rotor housing in spaced relation to radiate from the rotor housing, wherein as the rotor housing rotates the plurality of blades rotate. 14. The system of claim 8 , further comprising a linking arm coupled to the interface plate and the pitch drive assembly, the linking arm follows the rotation of the pitch drive assembly. 15. A method comprising: driving a blade pitch system having a set of locking holes; rotating, by a pitch drive assembly, the blade pitch system clockwise or counterclockwise within a range of angular degrees to adjust a blade pitch angle of a respective one blade in a plane perpendicular to a rotor center axis of rotation relative to a rotor housing; locking, by a pitch locking pin-and-hole system including an interface plate and at least one blade pitch lock assembly coupled to the interface plate, each blade pitch lock assembly including a locking pin having a pin center axis parallel with a center axis of a locking hole to engage a respective one locking hole of the set of locking holes in a locked state; operating a turbine in a non-power generating mode during the driving, rotating, and locking; and operating the turbine in a power genera